System and method for associating a geographic location with an internet protocol address

ABSTRACT

The present application is directed to systems and methods for associating a geographic location with an IP address. Generally, a plurality of localized search queries of search queries received at an Internet search engine are determined, where each of the plurality of localized search queries is associated with a location. A geo tag is associated with each of the plurality of localized search queries and a subset of the plurality of localized search queries that are associated with a first IP address is identified. The subset of the plurality of localized search queries is clustered into a spatial cluster including localized search queries associated with geo tags located within a defined distance of a geo tag associated with at least one other localized search query of the cluster. A geographic location associated with a geographic center of the cluster is then associated with the first IP address.

RELATED APPLICATIONS

The present application is related to U.S. patent application Ser. No.11/729,365, filed on Mar. 28, 2007, and U.S. patent application Ser. No.11/729,364, filed on Mar. 28, 2007.

BACKGROUND

Devices such as personal computers, servers, and handheld devices thataccess computer networks utilizing protocols such as the TCP/IP protocolare typically assigned an Internet Protocol Address (“IP address”) thatidentifies the device. An IP address is a unique number that may beassigned to a single device, or is shared by multiple client devices,and provides the ability to route data over a network to and from aspecific device.

Internet standards governing bodies such as the American Registry forInternet Numbers (“ARIN”) provide blocks of IP addresses to Internetservice providers. When a user provided Internet service by an Internetservice provider interacts with webpages available on the Internet, theuser sends various requests to a website provider that include an IPaddress of the block of IP addresses provided to the Internet serviceprovider. Because the Internet service provider may provide Internetservice to more users than the number of IP addresses provided to theInternet service provider, it may appear that more than one user isusing a single IP address. Thus, it is often difficult to determine alocation of a user submitting a request based on an IP addressassociated with the user because many different users in differentgeographic locations may use the same IP address.

Internet search engines such as Yahoo!, and online advertisement serviceproviders such as Yahoo! Search Marketing, often desire to determine alocation of a user submitting a search query, or a location of a userreceiving a digital ad, so that the Internet search engine or the onlineadvertisement service provider can better tailor search results ordigital ads to the potential interests of a user. For example, dependingon a local intent of a search query, an Internet search engine maydesire to serve search listings with information specifically tailoredto the location of the user. Similarly, an online advertisement serviceprovider may desire to serve digital ads such as banner ads or sponsoredsearch listings to a user regarding a store, or products and services,that are actually located near a user receiving the digital ad.

Due to the increased interest in targeting search results and digitalads based on a location of a user, improved methods for determining alocation of a user based on an IP address received with a search queryor a digital ad request are desirable.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of one embodiment of an environment in whichsystems and methods for associating a geographic location with an IPaddress may operate;

FIG. 2 is a block diagram of one embodiment of a system for associatinga geographic location with an IP address based on user activityassociated with registered users;

FIG. 3 is a flow chart of one embodiment of a method for associating ageographic location with an IP address based on user activity associatedwith registered users;

FIG. 4 is a diagram illustrating the creation of a spatial cluster;

FIG. 5 is a diagram illustrating one method for determining an accuracyscore at a zip code level of an association of a geographic locationwith an IP address;

FIG. 6 is a diagram illustrating one method for determining an accuracyscore at a city level of an association of a geographic location with anIP address;

FIG. 7 is a diagram illustrating one method for determining an accuracyscore at a designated market area (“DMA”) level of an association of ageographic location with an IP address;

FIG. 8 is a diagram illustrating one method for determining an accuracyscore at a state level of an association of a geographic location withan IP address;

FIG. 9 is a block diagram of one embodiment of a system for associatinga geographic location with an IP address based on user activityassociated with browser cookies;

FIG. 10 is a flow chart of one embodiment of a method for associating ageographic location with an IP address based on user activity associatedwith browser cookies;

FIG. 11 is a block diagram of one embodiment of a system for associatinga geographic location with an IP address based on a local intent ofsearch queries received at a search engine; and

FIG. 12 is a flow chart of one embodiment of a method for associating ageographic location with an IP address based on a local intent of searchqueries received at a search engine.

DETAILED DESCRIPTION OF THE DRAWINGS

The present disclosure is directed to systems and methods forassociating a geographic location with an IP address. Associating ageographic location with an IP address provides Internet search enginesand online advertisement service providers (“ad providers”) the abilityto better target search results and digital ads based on a location of auser. The present disclosure describes systems and methods forassociating a geographic location with an IP address based on, e.g.,user activity associated with registered users, user activity associatedwith browser cookies, and a local intent of search queries received at asearch engine.

FIG. 1 is a block diagram of one embodiment of an environment in whichsystems and methods for associating a geographic location with an IPaddress may operate. However, it should be appreciated that the systemsand methods described below are not limited to use with a search engineor pay-for-placement online advertising. The environment 100 includes aplurality of advertisers 102, an ad campaign management system 104, anad provider 106, a search engine 108, a website provider 110, and aplurality of Internet users 112. Generally, an advertiser 102 bids onterms and creates one or more digital ads by interacting with the adcampaign management system 104 in communication with the ad provider106. The digital ad may be a graphical banner ad that appears on awebsite viewed by Internet users 112, a sponsored search listing that isserved to an Internet user 112 in response to a search performed at asearch engine 108, a video ad, a graphical banner ad based on asponsored search listing, and/or any other type of online marketingmedia known in the art.

When an Internet user 112 performs a search at a search engine 108, thesearch engine 108 typically receives a search query and an IP addressassociated with the search query. In response to the search query, thesearch engine 108 returns search results including one or more searchlistings based on search terms within the search query provided by theInternet user 112. Additionally, the ad provider 106 may serve one ormore digital ads created using the digital ad campaign management system104 to the Internet user 112 based on search terms within the searchquery provided by the Internet user 112.

Similarly, when an Internet user 112 requests a website served by thewebsite provider 110, the ad provider 106 receives a digital ad request.The digital ad request may include data such as keywords obtained fromcontent of the website and an IP address. In response to the digital adrequest, the ad provider 106 serves one or more digital ads createdusing the ad campaign management system 104 to the Internet user 112based on the keywords within the digital ad request.

When the search engine 108 serves search listings, or the digital adprovider 106 serves digital ads, the search engine 108, the ad campaignmanagement system 104, and/or the ad provider 106 typically record andprocess information associated with the served search listings ordigital ads. For example, the search engine 108, the ad campaignmanagement system 104, and/or the ad provider 106 may record the searchterms that caused the search engine 108 to serve the search listings;the search terms that caused the ad provider 106 to serve the digitalads; whether the Internet user 112 clicked on a URL associated with aserved search listing or a served digital ad; what search listings ordigital ads the search engine 108 and/or the ad provider 106 served witheach search listings or digital ad; a rank or position of a digital adwhen the Internet user 112 clicked on the digital ad; and/or for eachsearch listing or digital ad, whether an Internet user 112 clicked on adifferent search listing or digital ad served at the same time. Oneexample of an ad campaign management system that may perform these typesof actions is disclosed in U.S. patent application Ser. No. 11/413,514,filed Apr. 28, 2006, and assigned to Yahoo! Inc.

In processing information associated with served search listings ordigitals ads, the search engine 108, the ad campaign management system104, the ad provider 106, and/or another module of the search engine 108or the ad provider 106 may associate a geographic location with an IPaddress based on IP addresses received with search queries or digital adrequests. The description below describes at least three differentsystems and methods for associating a geographic location with an IPaddress. Generally, FIGS. 2-8 illustrate systems and methods forassociating a geographic location with an IP address based on useractivity associated with registered users. FIGS. 9 and 10 illustratesystems and methods for associating a geographic location with an IPaddress based on user activity associated with browser cookies. FIGS. 11and 12 illustrate systems and methods for associating a geographiclocation with an IP address based on a local intent of search queriesreceived at a search engine.

FIG. 2 is a block diagram of one embodiment of a system for associatinga geographic location with an IP address based on user activityassociated with registered users. Generally, the system 200 includes asearch engine 202, a website provider 204, an ad provider 206, an adcampaign management system 208, and an IP address to location module210. In some implementations the IP address to location module 210 maybe part of the search engine 202 and/or the ad provider 206. However, inother implementations, the IP address to location module 210 is distinctfrom the search engine 202 and/or the ad provider 206. Typically thesearch engine 202, website provider 204, ad provider 206, ad campaignmanagement system 208, and IP address to location module 210 communicatewith one another over one or more external or internal networks. Thesearch engine 202, website provider 204, ad provider 206, ad campaignmanagement system 208, and IP address to location module 210 may beimplemented as software code stored on a computer-readable medium andrunning in conjunction with a processor such as a personal computer, asingle server, a plurality of servers, or any other type of computingdevice known in the art.

Search engines 202 and website providers 204 often provide theopportunity for a user to register with the search engine 202 and/orwebsite provider 204. Typically, as part of the process for registeringwith the search engine 202 and/or website provider 204, a user willprovide demographic information such as the user's gender, age,occupation, income level, home address, and/or business address. Toencourage a user to register, search engines 202 and/or websiteproviders 204 may provide the user with access to a free email account,special advertisements or discounts available only to registered users,access to restricted webpages available only to registered users, or anyother incentive a search engine 202 and/or website provider 204 maydesire to provide to registered users. When a user is registered, thesearch engine 202 and/or website provider 204 provide the registereduser with a unique identifier which allows the search engine 202 and/orwebsite provider 204 to monitor and record the activity of theregistered user. For example, the search engine 202 and/or websiteprovider 204 may monitor the types of search queries submitted by theregistered user, the webpages the registered user visits, what productsand services the registered user purchases, or any other user activityon the Internet that may be useful to the search engine 202 and/orwebsite provider 204.

In addition to the information recited above, the search engine 202and/or website provider 204 may monitor and record IP addressesassociated with the activity of registered users. The IP address tolocation module 210 processes the recorded user activity and the IPaddress associated with the activity of the registered user for aplurality of registered users to associate a geographic location with anIP address.

FIG. 3 is a flow chart of one embodiment of a method for associating ageographic location with an IP address based on user activity associatedwith registered users. The method 300 begins with a plurality of usersinteracting with a search engine and/or a website provider to registerwith the search engine or website site provider at step 302. Asdescribed above, the users provide demographic information whenregistering such as a home address of the user. The search engine and/orwebsite provider monitor and record the user activity of the pluralityof registered users at step 304. For example, the search engine and/orwebsite provider may monitor and record the types of search queriessubmitted by each registered user, the webpages each registered uservisits, the products and service each registered user purchases, and theIP address associated with each registered user. In one implementation,the search engine and/or website provider record the user activity insearch logs.

Systems such as an IP address to location module associate a geo tagwith each of the registered users at step 306 based on the location ofthe user provided during registration. Generally, a geo tag may be anidentifier assigning a longitude and latitude coordinate to a geographiclocation such as a home address or a business address associated withthe registered user. Examples of systems and methods for indexing datasuch as associating a geo tag with a geographic location associated witha user are disclosed in U.S. patent application Ser. No. 10/982,629,filed Nov. 4, 2004 and assigned to Yahoo! Inc., the entirety of which ishereby incorporated by reference.

In some implementations, the IP address to location module reviewsrecords associated with the plurality of registered users to remove anyduplicate entries for one user having multiple registered accounts atstep 308. After removing any duplicate entries, the IP address tolocation modules identifies one or more subsets of the plurality ofregistered users at step 310. Each subset of the plurality of registeredusers is associated with the same IP address, or a defined range of IPaddresses.

The IP address to location module examines a subset of the plurality ofregistered users to determine a geographic location associated with theIP address, or defined range of IP addresses, of the subset. Initially,the IP address to location module may examine the number of registeredusers in the subset to determine if the number of registered users inthe subset exceeds a quorum threshold at step 312. The quorum thresholdis a number of registered users that should be present in the subset toaccurately associate a geographic location with an IP address. In oneimplementation, the quorum threshold may be set at 50 registered users,but the quorum threshold may be set at any number of users.

If the IP address to location module determines that the number ofregistered users in the subset does not exceed the quorum threshold(314), the IP address to location module may add registered users to thesubset that are associated with an adjoining IP address at step 316 sothat the number of registered users in the subset exceeds the quorumthreshold. Typically an IP address adjoins another IP address when it isthe numerically closest IP address within the same Class-C subnet as theoriginal IP address. As known in the art, a Class-C subnet is an IPaddress block consisting of 256 consecutive addresses. In someimplementations, any registered users added to the subset must beassociated with an IP address that is in the same Class-C subnet as theoriginal IP address because different Class-C IP addresses have a highrisk of being routed differently.

In some implementations, the IP address to location module may limit thenumber of registered users added to the subset to a predefined ceiling.For example, the number of registered users added to a subset may not bemore than 25% of the total number of registered users in the subset.

If the IP address to location module determines the number of registeredusers in the subset exceeds the quorum threshold (317), or after addingregistered users to the subset so that the number of registered users inthe subset exceeds the quorum threshold at step 316, the method proceedsto step 318. In some implementations, the IP address to location modulemay normalize a weight associated with registered users at step 318.Normalizing a weight associated with registered users allows the IPaddress to location module to adjust the weight of each registered userin determining a geographic location associated with an IP address basedon factors such as a population of a geographic location associated witha registered user. If the weight associated with registered users is notnormalized, it is likely that a geographic location associated with anIP address will regularly be biased towards a geographic location with ahigh population density, such as a large city. To address this issue,the IP address to location module may normalize a weight associated witheach registered user so that registered users located in a highlypopulated area have less weight in determining a geographic locationassociated with an IP address than registered users located in sparselypopulated areas. However, in other implementations, the IP address tolocation module does not normalize a weight associated with theregistered users so that each user has the same weight in determining ageographic location associated with the IP address.

The IP address to location module creates a spatial cluster for thesubset at step 320. In one implementation, the IP address to locationmodule creates a spatial cluster for the subset based on registeredusers of the subset that have a geo tag located within a predefineddistance of a geo tag of another registered user of the cluster. In oneimplementation, the predefined distance may be 30 miles. However, anypredefined distance may be used. The IP to location module may set thepredefined distance based on factors such as a granularity of user dataavailable, e.g. a street address or zip code associated with aregistered user; a population density association with a geographiclocation associated with a registered user; adjacency relationships,such as those described in U.S. patent application Ser. No. 10/982,629,relating to distances between adjacent zip codes; or any other factordesired by the IP to location module. In other implementations, otheralgorithms for creating spatial clusters known in the art may be used.

FIG. 4 is a diagram illustrating how an IP address to location modulemay create a spatial cluster for one subset. The spatial cluster iscreated to determine a general location with the most number ofregistered users within a defined distance of one another that areassociated with the same IP address, or defined range of IP addresses.The IP address to location module creates a spatial cluster 402including a plurality of registered user 404 that are associated with ageo tag located within a predefined distance 406 of a geo tag of anotherregistered user of the cluster. It will be appreciated that the IPaddress to location module does not include registered users 408 thatare not within the predefined distance 406. Additionally, the IP addressto location module does not include minor clusters 410. Generally, Minorclusters 410 include fewer registered users than the spatial cluster402, and include registered users that are associated with a geo tagthat is located within a predefined distance of a geo tag of anotherregistered user of the minor cluster 410 but that is not located withina predefined distance of a geo tag of a registered user of the spatialcluster 410.

Referring again to FIG. 3, after the IP address to location modulecreates a spatial cluster for the subset at step 320, the IP address tolocation module determines a contributing point near the geographiccenter of the cluster at step 322. In one implementation, the IP addressto location module determines a contributing point by determining ageographic location, such as a longitude and latitude, that isassociated with more registered users of the cluster than any othergeographic location. However, when two or more geographic locations areequally associated with more registered users of the cluster than anyother geographic location, the IP address to location module determinesa contributing point to be the geographic location that is closest tothe average of all of the geographic locations associated withregistered users of the cluster, For example, with respect to longitudeand latitude coordinates, the IP address to location module woulddetermine the contributing point to be the geographic locationassociated with a registered user of the cluster that is closest to theaverage longitude and latitude of all of the longitudes and latitudesassociated with registered users of the cluster.

The IP address to location module assigns a geographic locationassociated with the determined geographic center of the cluster (thecontributing point) to the IP address, or defined range of IP addresses,shared by the registered users of the cluster at step 324. Thegeographic location associated with the geographic center of the clustermay be a street, a zip code, a neighborhood, a city, a state, a DMA, orany other geographic location. For example, if all registered users of acluster are associated with a single IP address, the IP location modulemay assign a zip code associated with the determined geographic centerof the cluster (the contributing point) with the single IP address.Similarly, if all registered users of a cluster are associated with oneof two sequential IP addresses, the IP location module may assign a zipcode associated with the determined geographic center of the cluster(the contributing point) with the two sequential IP addresses.

The IP address to location module may determine an accuracy score atstep 326 for the association of the geographic location with the IPaddress, or defined range of IP addresses, shared by the registeredusers of the cluster at step 324. The IP address to location module maydetermine the accuracy score on a street level, a zip code level, a citylevel, a DMA level, a state level, a country level, or any othergeographic level desired by a search engine and/or web provider.

FIG. 5 is a diagram illustrating one method for determining an accuracyscore on a zip code level of an association of a geographic locationassociated with the determined geographic center of a cluster (thecontributing point) with the IP address, or defined range of IPaddresses, shared by the registered users of the cluster. Generally, anaccuracy score on a zip code level is determined by dividing a totalnumber of registered users of the cluster in a zip code 502 that is alsothe zip code associated with the determined geographic center 504 of thecluster 506 by the total number of registered users in the cluster 506.

In FIG. 5, eight registered users of the cluster are in the zip code 502that is also the zip code associated with the determined geographiccenter 504 of the cluster 506. Further, there is a total of twenty-oneregistered users in the cluster 506. Therefore, the accuracy score isdetermined by dividing eight by twenty-one. Accordingly, the accuracyscore on a zip code level of the geographic location associated with theIP address, or defined range of IP addresses, shared by the registeredusers of the cluster 506 is 38.1%.

FIG. 6 is a diagram illustrating one method for determining an accuracyscore on a city level of an association of a geographic locationassociated with the determined geographic center of the a cluster (thecontributing point) with the IP address, or defined range of IPaddresses, shared by the registered users of the cluster. Generally, anaccuracy score on a city level is determined by dividing a total numberof registered users of the cluster in a city 602 that is also the cityassociated with the determined geographic center 604 of the cluster 606by the total number of registered users in the cluster 606.

In FIG. 6, sixteen registered users of the cluster are in the city 602that is also the city associated with the determined geographic center604 of the cluster 606. Further, there is a total of twenty-oneregistered users in the cluster 606. Therefore, the accuracy score isdetermined by dividing sixteen by twenty-one. Accordingly, the accuracyscore on a city level of the geographic location associated with the IPaddress, or defined range of IP addresses, shared by the resisted usersof the cluster 606 is 76.2%

FIG. 7 is a diagram illustrating one method for determining an accuracyscore on a DMA level of an association of a geographic locationassociated with the determined geographic center of a cluster (thecontributing point) with the IP address, or defined range of IPaddresses, shared by the registered users of the cluster. Generally, anaccuracy score on a DMA level is determined by dividing a total numberof registered users of the cluster in a DMA 702 that is also the DMAassociated with the determined geographic center 704 of the cluster 706by the total number of registered users in the cluster 706.

In FIG. 7, seventeen registered users of the cluster are in the DMA thatis also the DMA associated with the determined geographic center 704 ofthe cluster 706. Further, there is a total of twenty-one registeredusers in the cluster 706. Therefore, the accuracy score is determined bydividing seventeen by twenty-one. Accordingly, the accuracy score on aDMA level of the geographic location associated with the IP address, ordefined range of IP addresses, shared by the registered users of thecluster 706 is 80.9%.

FIG. 8 is a diagram illustrating one method for determining an accuracyscore on a state level of an association of a geographic locationassociated with the determined geographic center of a cluster (thecontributing point) with the IP address, or defined range of IPaddresses, shared by the registered users of the cluster. Generally, anaccuracy score on a state level is determined by dividing a total numberof registered users of the cluster in a state 802 that is also the stateassociated with the determined geographic center 804 of the cluster 806by the total number of registered users in the cluster 806.

In FIG. 8, twenty registered users of the cluster are in the state thatis also the state associated with the determined geographic center 804of the cluster 806. Further, there is a total of twenty-one registeredusers in the cluster 806. Therefore, the accuracy score is determined bydividing twenty by twenty-one. Accordingly, the accuracy score on astate level of the geographic location associated with the IP address,or defined range of IP addresses, shared by the registered users of thecluster 806 is 95.2%.

In addition to associating a geographic location with an IP addressbased on user activity associated with registered users, a geographiclocation may be associated with an IP address based on user activityassociated with browser cookies. FIG. 9 is a block diagram of oneembodiment of a system for associating a geographic location with an IPaddress based on user activity associated with browser cookies. Similarto the system 200 of FIG. 2, the system 900 includes a search engine902, a website provider 904, an ad provider 906, an ad campaignmanagement system 908, and an IP address to location module 910.

A browser cookie is typically a small text file that a website provider904 serves to a user. The browser cookie is stored locally by the userand is sent to the website provider 904 whenever the user requests asubsequent webpage from the website provider 904. One use of browsercookies is to set a geographic location for a user with a webpage suchas a webpage that provides local weather to a user or a webpage thatprovides local telephone listings to a user. Therefore, when a userreturns to the webpage, the user is automatically provided with localweather, or the user may search for local telephone listings withouthaving to again identify a geographic location of the user.

The search engine 902 and/or website provider 904 may receive one ormore browser cookies when a user submits a search query or requests awebpage. The search engine 902, the website provider 904, and/or the adprovider 906 may monitor and record user activity associated withreceived browser cookies. For example, for each browser cookiesreceived, the search engine 902, the website provider 904, and/or the adprovider 906 may record webpage requests or search requests receivedwith a browser cookie, search listings or digital ads served to a userin response to a request with a browser cookie, which search listings ordigital ads a user clicks on after sending a request with a browsercookie, or any other activity associated with a browser cookie desiredby the search engine 902, the website provider 904, and/or the adprovider 906. Similarly, the search engine 902, the website provider904, and/or the ad provider 906 may monitor and record IP addressesassociated with received browser cookies.

The IP address to location module 910 processes the recorded useractivity and IP addresses associated with the received browser cookiesto associate a geographic location with an IP address. FIG. 10 is a flowchart of one embodiment of a method for associating a geographiclocation with an IP address based on user activity associated withbrowser cookies. The method 1000 begins with a plurality of usersinteracting with a search engine and/or a website provider which resultsin a browser cookie being set with the user that identifies a geographiclocation such as a home address or a business address of a user at step1002. The search engine, website provider, and/or ad provider monitorand record activity associated with the plurality of browser cookies andassociated users at step 1004. For example, the search engine and/orwebsite provider may monitor and record the types of search queriesassociated with a browser cookies, viewed webpages associated with abrowser cookie, purchased products and service associated with a browsercookie, and an IP address associated with a browser cookie. In oneimplementation, the search engine, website provider, and/or ad providerrecords activity associated with browser cookies in search logs.

An IP address to location module associates a geo tag with each of thebrowser cookies and associated users at step 1006 based on thegeographic location, such as the home address or business address,identified in the browser cookie. Generally, a geo tag may be anidentifier assigning a longitude and latitude coordinate to a geographiclocation such as a home address or business address with a browsercookie. One example of systems and methods for indexing data such asassociating a geo tag with a geographic location such as a home addressor business address identified in a browser cookie is disclosed in U.S.patent application Ser. No. 10/982,629, filed Nov. 4, 2004, and assignedto Yahoo! Inc.

In some implementations, the IP address to location module reviewsrecords associated with the plurality of browser cookies and associatedusers to remove any duplicate entries for multiple browser cookiesassociated with the same user at step 1008. After removing any duplicateentries, the IP address to location modules identifies one or moresubsets of the plurality of browser cookies and associated users at step1010. Each subset of the plurality of browser cookies and associatedusers is associated with the same IP address, or a defined range of IPaddresses.

The IP address to location module examines a subset of the plurality ofbrowser cookies and associated users to determine a geographic locationassociated with the IP address, or defined range of IP addresses, of thesubset. Initially, the IP address to location module may examine thenumber of browser cookies and associated users in the subset todetermine if the number of browser cookies and associated users in thesubset exceeds a quorum threshold at step 1012.

If the IP address to location module determines the number of browsercookies and associated users in the subset does not exceed the quorumthreshold (1014), the IP address to location module may add browsercookies and associated users to the subset that are associated with anadjoining IP address at step 1016 so that the number of browser cookiesand associated users in the subset exceeds the quorum threshold.

If the IP address to location module determines the number of browsercookies and associated users in the subset exceeds the quorum threshold(1017), or after adding browser cookies and associated users to thesubset so that the number of browser cookies and associated users in thesubset exceeds the quorum threshold at step 1016, the method proceeds tostep 1018. In some implementations, the IP address to location modulemay normalize a weight associated with browser cookies and associatedusers at step 1018. As discussed above, normalizing a weight associatedwith browser cookies allows the IP address to location module to adjustthe weight of each browser cookie in determining a geographic locationassociated with an IP address based on factors such as the populationdensity of a geographic location associated with a browser cookie. Ifthe weight associated with the browser cookies is not normalized, it islikely that a geographic location associated with an IP address willregularly be biased towards a geographic location with a high populationdensity, such as a large city. To address this issue, an IP address tolocation module may normalize a weight associated with a browser cookiesso that users submitting browser cookies that are located in a highlypopulated area have less weight in determining a geographic locationassociated with an IP address than users submitting browser cookies thatare located in sparsely populated areas. However, in otherimplementations, the IP address to location module does not normalize aweight associated with browser cookies and associated uses so that eachbrowser cookie and associated user has an equal weight in determining ageographic location associated with an IP address.

The IP address to location module creates a spatial cluster for a subsetat step 1020 as described above with respect to FIGS. 3 and 4. In oneimplementation, the IP address to location module creates a spatialcluster by associating all browser cookies and associated users with geotags that are located within a predefined distance of a geo tag ofanother browser cookies and associated user of the cluster. However,other algorithms for creating spatial clusters known in the art may beused.

After the IP address to location module creates a spatial cluster forthe subset, the IP address to location module determines a contributingpoint near the geographic center of the cluster at step 1022. The IPaddress to location module then associates a geographic location of thedetermined geographic center of the cluster (the contributing point)with the IP address, or defined range of IP addresses, shared by thebrowser cookies and associated users of the cluster at step 1024. Thegeographic location associated with the geographic center of the clustermay be a street, a zip code, a neighborhood, a city, a state, a DMA, orany other geographic location. For example, if all browser cookies andassociated users of a cluster are associated with a single IP address,the IP location module may associate a zip code associated with thedetermined geographic center of the cluster (the contributing point)with the single IP address. Similarly, if all browser cookies andassociated users of a cluster are associated with one of two sequentialIP addresses, the IP location module may associate a zip code associatedwith the determined geographic center of the cluster (the contributingpoint) with the two sequential IP addresses.

The IP address to location module may determine an accuracy score atstep 1026 of the geographic location associated with the IP address, ordefined range of IP addresses, shared by the browser cookies andassociated users of the cluster at step 1024. Similar to that describedabove with respect to FIGS. 5-8, the IP address to location module maydetermine the accuracy score on a street level, a zip code level, a citylevel, a DMA level, a state level, a country level, or any othergeographic level desired by a search engine and/or web provider.

In addition to associating a geographic location with an IP addressbased on user activity associated with registered users or user activityassociated with browser cookies, a geographic location may be associatedwith an IP address based on a local intent of search queries received ata search engine. FIG. 11 is a block diagram of one embodiment of asystem for associating a geographic location with an IP address based ona local intent of search queries received at a search engine. Similar tothe systems 200, 900 of FIGS. 2 and 9, the system 1100 includes a searchengine 1102, a website provider 1104, an ad provider 1106, an adcampaign management system 1108, and an IP address to location module1110.

A local intent of a search query indicates a degree of confidence that auser submitting the search query desires search results relating to thelocation of the user. For example, a search query “Dentist Pasadena” hasa high local intent because a user submitting the search query is likelylocated in or near Pasadena, Calif. and searching for a local dentist.It will be appreciated that for a search query to have a high localintent, it is not necessary for the search query to include an explicitlocation. For example, a search query of “Dentist” has a higher localintent than a search query of “Holiday” because a user submitting thesearch query “Dentist” is more likely to require a local dentist than auser submitting the search query “Holiday” requiring a local holiday.

As the search engine 1102 receives search queries from a plurality ofusers, the search engine 1102 determines a local intent of the searchqueries and records information such as the search query, a local intentassociated with the search query, and an IP address associated with thesearch query. The IP address to location module 1110 processes therecorded search queries, local intent of each of the search queries, andIP address associated with the received search queries to associate ageographic location with an IP address. FIG. 12 is a flow chart of oneembodiment of a method for associating a geographic location with an IPaddress based on a local intent of search queries received at a searchengine.

The method 1200 begins at step 1202 with a search engine receiving aplurality of search queries from users and recording informationassociated with the received search queries. The IP address to locationmodule determines a plurality of localized search queries of theplurality of receive search queries at step 1204. In one implementation,the IP address to location module determines the plurality of localizedsearch queries based on whether each search query contains an explicitgeographic location and a term that is known to have a high degree oflocal intent.

Examples of systems and methods for identifying whether a search queryincludes an explicit geographic location are disclosed in U.S. patentapplication Ser. No. 10/680,495, filed Oct. 7, 2003 and assigned toYahoo! Inc., the entirety of which is hereby incorporated by reference.Generally, as described in U.S. patent application Ser. No. 10/680,495,to determine an explicit geographic location in a search query, thesearch query is parsed into text including a name of a geographiclocation and text that does not include a name of a geographic location.An explicit geographic location associated with the search query is thendetermined based on factors such as one or more names of geographiclocations in the search query; whether for any of the names ofgeographic locations in the search query, multiple geographic locationsexist with the same name; relationships between any of the geographiclocations named in the search query; and relationships between thegeographic locations named in the search query and the text of thesearch query that does not include a name of a geographic location.

Examples of systems and methods for determining whether a term has ahigh degree of local intent are disclosed in U.S. patent applicationSer. No. 11/729,103, titled “System for Providing GeographicallyRelevant Content to a Search Query with Local Intent;” U.S. patentapplication Ser. No. 11/729,104, titled “System for Determining theGeographic Range of Local Intent in a Search Query;” and U.S. patentapplication Ser. No. 11/729,096, titled “System for Determining LocalIntent in a Search Query,” each of which were filed Mar. 28, 2007, andassigned to Yahoo! Inc., the entirety of each of which is herebyincorporated by reference. Generally, as described in U.S. patentapplication Ser. Nos. 11/729,103, 11/729,104, and 11/729,096,potentially millions of search queries are examined to establish whichterms in search queries tend to be associated with locations that arenear a location of a user submitting the search query. For example, ifmany search queries show that users search for the term “Dentist” inlocations near where the users are located, such as a search query“Dentist Pasadena ” for a user located in Pasadena, the term “Dentist”is deemed to have a high local intent. Similarly, if many search queriesshow that users search for the term “Pizza Delivery” in locations nearwhere the users are located, such as a search query “Pizza DeliveryLincoln Park” for a user located in Lincoln Park, the term “PizzaDelivery” is deemed to have a high local intent. Conversely, if manysearch queries show that users search for the term “Flight” in locationsthat are not necessarily near locations where users are located, such asa search query “Flight Hawaii” for a user located in Chicago, the term“Flight” is deemed to have a low local intent. In one implementation, adegree of local intent of a term may be assigned a value on a scale ofzero to one, with a local term such as “Dentist” assigned a value nearone, and a less local term such as “DVD” assigned a value near zero.

After determining the plurality of localized search queries, the IPaddress to location module associates a geo tag with each of thelocalized search queries at step 1206. Generally, the IP address tolocation module associates a longitude and latitude coordinate to thelocalized search query based on the explicit geographic location in thelocalized search query. For example, the IP address to location modulemay associate a longitude and latitude of Pasadena, Calif. for thesearch query “Dentist Pasadena.” Examples of systems and methods forindexing data such as associating a geo tag with an explicit geographiclocation are disclosed in U.S. patent application Ser. No. 10/982,629,filed Nov. 4, 2004, and assigned to Yahoo! Inc.

The IP address to location module determines one or more subsets of theplurality of localized search queries at step 1208. Each subset of theplurality of localized search queries is associated with the same IPaddress, or a defined range of IP addresses.

The IP address to location module examines a subset of the plurality oflocalized search queries to determine if the number of search queries inthe subset exceeds a quorum threshold at step 1212. If the IP address tolocation module determines the number of search queries in the subsetdoes not exceed the quorum threshold (1214), the IP address to locationmodule may add search queries to the subset that are associated with anadjoining IP address at step 1216 so that the number of search queriesin the subset exceeds the quorum threshold.

If the IP address to location module determines the number of searchqueries in the subset exceeds the quorum threshold (1217), or afteradding localized search queries to the subset so that the number oflocalized search queries in the subset exceeds the quorum threshold atstep 1216, the method proceeds to step 1218. In some implementations,the IP address to location module may normalize a weight associated withlocalized search queries at step 1218. As discussed above, an IP addressto location module may normalize a weight associated with a localizedsearch query to adjust the weight of the localized search query indetermining a geographic location associated with an IP address based onfactors such the population density of a geographic location associatedwith a localized search query. If the weight associated with thelocalized search query is not normalized, it is likely that a geographiclocation associated with an IP address will regularly be biased towardsa geographic location with a high population density, such as a largecity. To address this issue, an IP address to location module maynormalize a weight associated with a localized search query at step 1218so that localized search queries associated with a geographic locationthat is highly populated will have less weight in determining ageographic location associated with an IP address than search queriesassociated with a geographic location that is sparsely populated.However, in other implementations, the IP address to location moduledoes not normalize the weight associated with the search queries so thateach search query has an equal weight in determining a geographiclocation associated with an IP address.

The IP address to location module creates a spatial cluster of a subsetof the plurality of localized search queries at step 1220 as describedabove with respect to FIGS. 3 and 4. In one implementation, the IPaddress to location module creates a spatial cluster by associating alllocalized search queries of the subset with a geo tag that is locatedwithin a predefined distance of a geo tag of another localized searchquery of the cluster. However, other algorithms for creating spatialclusters know in the art may be used.

After the IP address to location module creates a spatial cluster, theIP address to location module determines a contributing point near thegeographic center of the cluster at step 1222. The IP address tolocation module then associates a geographic location of the determinedgeographic center of the cluster (the contributing point) with the IPaddress, or defined range of IP addresses, shared by the localizedsearch queries of the cluster at step 1224. The geographic locationassociated with the geographic center of the cluster may be a street, azip code, a neighborhood, a city, a state, a DMA, or any othergeographic location. For example, if all localized search queries of acluster are associated with a single IP address, the IP location modulemay associate a zip code associated with the determined geographiccenter of the cluster (the contributing point) with the single IPaddress. Similarly, if all localized search queries of a cluster areassociated with one of two sequential IP addresses, the IP locationmodule may associate a zip code associated with the determinedgeographic center of the cluster (the contributing point) with the twosequential IP addresses.

The IP address to location module may additionally determine an accuracyscore at step 1226 of the geographic location associated with the IPaddress, or defined range of IP addresses, shared by the localizedsearch queries of the cluster at step 1224. Similar to that describedabove with respect to FIGS. 5-8, the IP address to location module maydetermine the accuracy score on a street level, a zip code level, a citylevel, a DMA level, a state level, a country level, or any geographiclevel desired by a search engine and/or web provider.

An illustrative example of the above-described method is describedbelow. Table 1 is an example of a set of search queries received at asearch engine.

TABLE 1 IP Address Search Query Local Intent 217.12.14.240

0.88 217.12.14.240

0.89 217.12.14.241

0.82 217.12.14.241 Caf{acute over (e)} New York 0.79 217.12.14.242

0.77 217.12.14.242 Flight Paris 0.38 217.12.14.242 Flight Hawaii 0.00217.12.14.243 Visual Basic 0.00 217.12.12.243 Perl Reference 0.00217.12.14.243 Lost 0.18

In Table 1, six search queries are determined to be highly localizedsearch queries (shown in bold) with an explicit location and a highlocal intent. When geo tags are associated with the highly localizedsearch queries and the highly localized search queries are clustered asdescribed above, five of the six search queries with explicit locationsand a high local intent (shown in bold and italics) refer to London.Accordingly, an IP address to location module can determine there is ahigh likelihood that the IP address range of 217.12.14.240 to217.12.14.242 is located in London since the majority of queries havingexplicit location terms and high local intent non-location terms havesimilar or same IP addresses.

FIGS. 1-12 disclose systems and methods for associating a geographiclocation with an IP address based on user activity associated withregistered users, user activity associated with browser cookies, and alocal intent of search queries received at the search engine.Associating a geographic location with an IP address provides Internetsearch engine and online advertisement service providers the ability tobetter target search results and digital ads based on a location of auser.

For example, after associating a geographic location with an IP address,an IP address to location module may export the association to anInternet search engine or an ad provider. Therefore, when the Internetsearch engine receives a subsequent search query associated with thesame IP address, the Internet search engine may determine a location ofthe user submitting the search query based on the association betweenthe geographic location and the IP address received from the IP addressto location model. The Internet search engine may then return searchresults relating to the search query specifically tailored to thelocation of the user submitting the search query.

Similarly, when the ad provider receives a digital ad request associatedwith the same IP address, the ad provider may determine a location ofthe user that will receive the digital ads based on the associationbetween the geographic location and the IP address received from the IPaddress to location module. The ad provider may then return digital adssuch as sponsored search listings or graphical banner ads tailored tothe location of the user receiving the digital ads. For example, the adprovider may serve digital ads relating to products and servicesactually available near the geographic location of the user receivingthe digital ads.

It is therefore intended that the foregoing detailed description beregarded as illustrative rather than limiting, and that it be understoodthat it is the following claims, including all equivalents, that areintended to define the spirit and scope of this invention.

1. A computer-implemented method for associating a geographic locationwith an internet protocol (“IP”) address, the method comprising thesteps of: determining with a processor a plurality of localized searchqueries of search queries received at an Internet search engine, eachsearch query of the plurality of localized search queries associatedwith a geographic location; associating with a processor a geo tag witheach search query of the plurality of localized search queries;identifying with a processor a subset of search queries of the pluralityof localized search queries that are associated with a first IP address;clustering with a processor the subset of search queries of theplurality of localized search queries into a spatial cluster comprisinglocalized search queries associated with geo tags identifying locationslocated within a defined distance of a location identified in a geo tagassociated with at least one other localized search query of the spatialcluster; and storing in a memory with a processor an association betweena geographic location associated with a geographic center of the spatialcluster and the first IP address.
 2. The method of claim 1, furthercomprising: determining with a processor whether a number of localizedsearch queries in the subset of search queries of the plurality oflocalized search queries exceeds a quorum threshold.
 3. The method ofclaim 2, further comprising: adding with a processor one or morelocalized search queries of the plurality of localized search queriesassociated with an IP address adjoining the first IP address to thesubset of search queries so that the number of localized search queriesin the subset of search queries exceeds the quorum threshold.
 4. Themethod of claim 1, further comprising: normalizing with a processor aweight associated with at least one localized search query of the subsetof search queries of the plurality of localized search queries based ona population density of a geographic location associated with the atleast one localized search query.
 5. The method of claim 1, whereinstoring with a processor an association between a geographic locationassociated with a geographic center of the spatial cluster and the firstIP address comprises: determining with a processor a geographic locationassociated with a geographic center of the spatial cluster; andassociating with a processor the determined geographic locationassociated with the geographic center of the spatial cluster with thefirst IP address.
 6. The method of claim 5, further comprising:determining with a processor an accuracy score of the associationbetween the determined geographic location and the first IP address on azip code level based on a number of localized search queries in thespatial cluster associated with the same zip code as the geographiccenter of the spatial cluster and a total number of localized searchqueries in the spatial cluster.
 7. The method of claim 5, furthercomprising: determining with a processor an accuracy score of theassociation between the determined geographic location and the first IPaddress on a city level based on a number of localized search queries inthe spatial cluster associated with the same city as the geographiccenter of the spatial cluster and a total number of localized searchqueries in the spatial cluster.
 8. The method of claim 5, furthercomprising: determining with a processor an accuracy score of theassociation between the determined geographic location and the first IPaddress on a designated market area (“DMA”) level based on a number oflocalized search queries in the spatial cluster associated with the sameDMA as the geographic center of the spatial cluster and a total numberof localized search queries in the spatial cluster.
 9. The method ofclaim 5, further comprising: determining with a processor an accuracyscore of the association between the determined geographic location andthe first IP address on a state level based on a number of localizedsearch queries in the spatial cluster associated with the same state asthe geographic center of the spatial cluster and a total number oflocalized search queries in the spatial cluster.
 10. The method of claim1, further comprising: exporting with a processor the associationbetween the geographic location and the first IP address to a searchengine.
 11. The method of claim 1, further comprising: exporting with aprocessor the association between the geographic location and the firstIP address to an online advertisement service provider.
 12. Acomputer-readable storage medium comprising a set of instructions forassociating a geographic location with an Internet Protocol (“IP”)address, the set of instructions to direct a processor to perform theacts of: determining a plurality of localized search queries of searchqueries received at an Internet search engine, each search query of theplurality of localized search queries associated with a location;identifying a subset of search queries of the plurality of localizedsearch queries that are associated with a first IP address; clusteringthe subset of search queries of the plurality of localized searchqueries into a spatial cluster comprising localized search queriesassociated with locations located within a defined distance of alocation associated with at least one other localized search query ofthe spatial cluster; and storing an association between a geographiclocation associated with a geographic center of the spatial cluster andthe first IP address.
 13. The computer-readable storage medium of claim12, further comprising a set of instructions to direct the processor toperform the acts of: recording an IP address associated with each searchquery of the plurality of localized search queries when the searchqueries are received at a search engine.
 14. A system for associating ageographic location with an Internet protocol (“IP”) address, the systemcomprising: an IP address to location module comprising a memory and aprocessor, the processor operative to execute instructions stored in thememory such that the IP address to location module is operative toprocess at least one search log to determine a plurality of localizedsearch queries, each search query of the plurality of localized searchqueries associated with a location, to identify a subset of searchqueries of the plurality of localized search queries that are associatedwith a first IP address, to cluster the subset of search queries of theplurality of localized search queries into a spatial cluster comprisinglocalized search queries associated with locations located within adefined distance of a location associated with at least one otherlocalized search query of the spatial cluster; and to store anassociation between a geographic location associated with a geographiccenter of the spatial cluster with the first IP address.
 15. The systemof claim 14, further comprising: a search engine in communication withthe IP address to location module, the search engine operative toreceive the plurality of localized search queries and record informationassociated with the received localized search queries to generate atleast a part of the at least one search log.
 16. The system of claim 15,further comprising: an online advertisement service provider incommunication with the IP address to location module, the onlineadvertisement service provider operative to serve digital ads related tothe localized search queries and record information associated with theserved digital ads to generate at last a part of the at least one searchlog.
 17. The system of claim 14, wherein the IP address to locationmodule is operative to determine an accuracy score associated with theassociation of the geographic location and the first IP address on atleast one of a zip code level, a city level, a designated market area(“DMA”) level, and a state level.
 18. The system of claim 14, whereinthe IP address to location module is further operative to export theassociation of a geographic location with the first IP address to atleast one of a search engine and an online advertisement serviceprovider.